Cell Culture Media for Enhanced Protein Production

ABSTRACT

Culture media for in vitro cell culture which contain substantially saturated amounts of selected amino acids improve protein production, constrain cell growth and extend cell longevity, methods for the production and use of such media, and systems fox the production of protein utilizing such media and methods.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation application of U.S. application Ser. No. 10/264,979 filed Oct. 4, 2002, now issued as U.S. Pat. No. 7,601,535; which is a continuation-in-part application of U.S. application Ser. No. 08/833,500 filed Apr. 7, 1997, now abandoned. The disclosure of each of the prior applications is considered part of and is incorporated by reference in the disclosure of this application.

BACKGROUND OF INVENTION

1. Field of Invention

The present invention is directed to culture media for in vitro cell culture which improve protein production, constrain cell growth and extend cell longevity, and to methods for the production and use of such media.

2. Background Information

The increasing demand for monoclonal antibodies (MABs) useful in research, diagnosis, therapy, and purification purposes has created a need to optimize protein production techniques. The prior art includes improved bioreactor designs and bioreactor operation to increase cell densities or the longevity of the cell culture by nutrient feedings.

Bioreactors have been operated in fed-batch, immobilized, perfusion and continuous modes. Alternate strategies, such as the use of temperature, media formulation, including the addition of mouse peritoneal factors, growth inhibitors, autocrine factors or cyclic mononucleotides and hyperstimulation by osmolarity stress, have been used to enhance protein production. These approaches have shown only marginal success.

Commonly used basal cell culture media are RPMI 1640, DMEM (Dulbecco's modified Eagle's medium), Ham's F12 and DMEM/F12 (DF). A modified medium, eRDF, prepared from RDF (RPMI:DMEM:F12, 2:1:1) by enrichment with amino acids, glucose and vitamins, was described by Murakami, H. (1989) “Serum-free media used for cultivation of hybridomas.” In: A. Mizrahi (Ed.), Advances in Biotechnological Processes, Vol. 11, Monoclonal Antibodies: Production and Application. Alan R. Liss, New York, pp. 107-141. Murakami showed that doubling the total amino acids or glucose alone in the culture medium did not increase cell density, but concurrent elevation of amino acids and glucose maximized the cellular growth by threefold.

Hyper-stimulation of monoclonal antibody production by high osmolality stress in an eRDF medium is described in Chua, F., et al. (1994) J. Immunological Methods 167:109-119, and Chua, F., et al. (1994) J. Biotechnology 37:265-275. However, the maximum IgG concentration achieved was about 300 μg/mL and 270 μg/mL for HG11 and TBC3 cells, respectively, at medium osmolarities about 350 to 400 mOsm. Further increase in osmolarity of the therein-described media with NaCl caused deterioration in antibody production.

Oh, S. K. W., et al. ((1995) Biotechnology and Bioengineering 48:525-535) report that hybridomas increased metabolic activities and amino acids uptake via the Na⁺ dependent symports to compensate for the osmotically elevated external environment.

Oh, S. K. W., et al. ((1996) “Flow Cytometric Studies of Osmotically Stressed and Sodium Butyrate-Treated Hybridoma Cells” in Flow Cytometry Applications in Cell Culture, Marcel Dekker, Inc., (Eds. M. Al-Rubeai and A. N. Emergy) New York, Basel, Hong Kong, pp. 101-119) also describes the application of flow cytometry in examining the relationships between total cellular monoclonal antibody content, cell size, and cell cycle distribution of hybridomas subjected to environmental stress.

SUMMARY OF THE INVENTION

The present invention provides methods and compositions for cell culture nutrient media which improves protein production, constrains cell growth and extends cell longevity.

In one aspect, the invention provides a cell culture medium for maintaining and proliferating cultured cells in vitro and the production of protein therefrom. The media comprises an aqueous solution comprising an amino acid component comprising at least one essential amino acid in its individual substantially saturated concentration in the aqueous solution when the aqueous solution is maintained at a temperature in the range of 30° to 50° C., and a basal medium component comprising such mineral salts, carbohydrates, nucleic acids, vitamins, lipids, and other compounds as are necessary to the viability and proliferation of cultured cells in vitro.

In certain embodiments of the invention, the dry weight of the amino acid component of the aqueous solution comprises at least 20% of the total dry weight of all solid constituents contained in the medium. Also in certain embodiments of the invention, the osmolarity of the aqueous solution is from approximately 320 to 450 mOsm.

Other aspects of the present invention provide methods for preparing media of the present invention, methods for culturing cells in vitro and systems for the production of proteins utilizing the media of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 graphically depicts the growth of hybridomas 2HG11 and TBC3 in medium BTC-28101 of the invention and in control medium DMEM/F12;

FIGS. 2A through 2D graphically depict the results of hollow fiber bioreactor examples in which medium BTC-28101 was utilized as the cell culture medium, wherein

FIG. 2A displays the levels of antibody produced by cell cultures over time,

FIG. 2B depicts pH variations for the medium over time,

FIG. 2C depicts the glucose utilization over time, and

FIG. 2D displays cell viability over time;

FIGS. 3A and 3B graphically depict the growth of hybridoma 2HG11 and the production of antibody, wherein

FIG. 3A graphically depicts the comparative growth of hybridoma 2HG11 in serum-free BTC-28101 and commercial media Hb and PFHM available from Gibco;

FIG. 3B graphically depicts IgG concentration produced from hybridoma 211G11 grown in serum-free BTC-28101 and commercial media Hb and PFHM available from Gibco;

FIG. 4 graphically depicts the comparative growth of hybridomas 2HG11 and TBC3 in medium BTC-28102 of the invention and in control medium DMEM/F12;

FIG. 5 graphically depicts the comparative growth of CHO cells in medium BTC-28103 of the invention and in control Iscove's Modified Dulbecco's Medium; and

FIG. 6 graphically presents a correlation of percent dry weight of amino acid in the media with MAB production in μg/mL, wherein D/F refers to a 1:1 mixture of Dulbecco's Modified Eagle Medium and Nutrient Mixture F-12 (DMEM/F12).

DETAILED DESCRIPTION OF THE INVENTION

The present invention provides methods and compositions for cell culture nutrient media which improves protein production, constrains cell growth and extends cell longevity.

In one aspect, the invention provides a cell culture medium for maintaining and proliferating cultured cells in vitro and the production of protein therefrom, The media comprises an aqueous solution comprising an amino acid component comprising at least one essential amino acid in its individual substantially saturated concentration in the aqueous solution when the aqueous solution is maintained at a temperature in the range of 30° to 50° C., and a basal medium component comprising such mineral salts, carbohydrates, nucleic acids, vitamins, lipids, and other compounds as are necessary to the viability and proliferation of cultured cells in vitro.

In the present description, the following terms will have the indicated definitions, unless a contrary definition is evident from the context in which the term is used.

As used herein, the term “cell culture medium” refers to any nutrient medium in which cells of any type may be cultured in vitro.

As used herein, the term “bioreactor” refers to any device in which cells may be cultured. Includes stationary flasks, spinner flasks and hollow fiber bioreactors.

As used herein, the term “basal medium” refers to any cell culture medium that contains all of the ingredients essential to cell metabolism, e.g., amino acids, lipids, carbohydrates, vitamins and mineral salts. RPMI, DMEM, Ham's 12, and eRDF are examples of basal media.

As used herein, the term “essential amino acid” refers to those amino acids not produced endogenously (or because it or a critical precursor is not produced in sufficient quantity to sustain cell growth, longevity and protein production) by cellular metabolism of cells. Although the list of amino acids defined as essential varies widely depending upon the cell type, for most types of mammalian cells in culture such amino acids are generally recognized to include arginine (Arg), cysteine (Cys), glutamine (Gln), histidine (His), isoleucine (Ile), leucine (Leu), lysine (Lys), methionine (Met), phenylalanine (Phe), proline (Pro), threonine (Thr), tryptophan (Trp), tyrosine (Tyr), and valine (Val). Of this list, cysteine, glutamine, proline and tyrosine are the amino acids most frequently defined as non-essential, depending upon the particular cell type in culture. For example, tyrosine is a non-essential amino acid in albino rat cells, but its synthesis requires the essential amino acid phenylalanine. Likewise, cysteine requires methionine, and proline and glutamine require glutamic acid.

As used herein, the term “non-essential amino acid” refers to those amino acids produced endogenously by cells in sufficient quantity to sustain cell growth, longevity and protein production. Although the list of amino acids defined as non-essential varies widely depending upon the cell type, for mammalian cells in culture such amino acids are generally recognized to include alanine (Ala), asparagine (Asn), aspartic acid (Asp), glutamic acid (Glu), glycine (Gly), and serine (Ser), with the recognized qualifications outlined previously.

As used herein, the term “DMEM/F12” refers to a mixture of Dulbecco's Modified Eagle's Medium and Ham's F12 in 1:1 proportions).

As used herein, the term “substantially saturated” refers to the limits of solubility for a particular substance as a component of the cell culture medium under particular physical conditions such as temperature. Solubility refers to the mass of the substance contained in the liquid; when this mass is at equilibrium with an excess of the substance, the solution is said to be saturated. Substantially saturated is therefore taken to mean approximately the point at which the substance will precipitate out of solution (or will not continue to dissolve) under the defined physical conditions.

General Features of the Media

The invention provides media and methods for improving protein production in cultures of protein producing cells, as well as an improved protein production system. In particular, the invention comprises culturing cells, including hybridomas and other antibody producing cells, as well as cells producing recombinant proteins, in an aqueous medium comprising a high concentration of amino acids, in particular the essential amino acids for a chosen cell type, and typically an energy source such as glucose or sucrose. The medium is substantially saturated at around 40° C. with an amino acid or mixture of amino acids essential to the metabolism of the cultured cells. The medium of the invention can contain approximately 5.50 to approximately 20 grams per liter of total or gross amino acids in solution or suspension and, in addition, approximately 5.50 to approximately 20 grams per liter of a carbohydrate energy source, preferably glucose, in solution. The gross amino acids content of the present media desirable comprise at least 20%, and preferably from about 25% to about 50%, of the total dry weight of the medium components. The present media will typically display a high level of osmolarity, and the cells may appropriately be adapted to the high osmolarity media of this invention by passaging.

A unique feature of the present media is that, by providing a maximized amount of certain media components by substantially saturating the aqueous solution, an adequate supply of nutrients is maintained from the initiation of the culture.

Increasing the concentrations of the selected media components inevitably increases the osmolarity, to a point far in excess of that found in most prior art basal media. The osmolarity of the present media is generally from approximately 320 to approximately 450 mOsm. Sodium chloride is the preferred osmolyte in the event it is desired to increase the osmolarity of the present media beyond that established by the various media components.

The media and the methods of the invention are useful in all forms of bioreactors. The benefits of the invention are realized in static, batch, shaker flask, and spinner flask and hollow fiber bioreactor culture procedures. Of particular benefit is the use of the present media in batch mode, which can be performed with less user intervention than fed-batch cultures.

Amino Acid Uptake and Metabolism

Amino acid transport regulation in animal cells is controlled by both sodium ion (Na⁺) dependent and independent transport systems. The Na⁺ dependent group consists of systems A, ASC, N, Gly, and β. Both systems A and ASC are ubiquitous in mammalian cells. It is reported that the primary mechanism for uptake of amino acids by cells is via sodium ion (Na⁺) dependent transport systems, including cell transport system A. System A is primarily responsible for the increased uptake of amino acids in high osmolarity media, and this effect is enhanced where Na⁺ ions are a substantial part of the osmolarity of the media. Thus, in the media of the present invention, it is desirable that one or more of the amino acids present in substantially saturated concentration be reactive with cell transport system A.

In addition, where it is deemed desirable to increase the osmolarity of the media beyond that provided by the various amino acids and basal media constituents, then sodium chloride would be the preferred osmolyte. At the same time, it is desirable that the ratio of Na⁺ ions to potassium ions (K⁺) be maintained at approximately normal levels (e.g. 20:1), in order to optimize amino acid uptake.

As discussed below, the media of the present invention appear, under certain circumstances, to allow the cultured cells to derive a significant portion of their energy requirements from sources other than the traditional carbohydrates such as glucose. The amino acids of the present media can serve as a preferential energy source for cell metabolism, thus reducing the reliance of the cells on supplied carbohydrates in the media.

Media Components

In order to provide a cell culture medium in accordance with the present invention, the various constituents recognized as constituting the requirements for a basal medium must be addressed. These constituents typically include amino acids, inorganic mineral salts, energy sources such as carbohydrates and other carbon sources, vitamins and co-factors, nucleic acids and derivatives, lipids and derivatives, as well as buffers and, typically, visual pH indicators to facilitate the monitoring of the cell culture medium. It is well known that animal cells have a need for certain ionic, nutrient, matrix protein attachment and growth factors in order to thrive. These elements are related to the requirements for growth and development.

The inorganic salts in culture media have two major functions. First, salt concentrations are ordinarily adjusted to approach the natural salt concentration levels from which the cells are derived. This is to minimize any deviation in osmotic pressure on the cells that would require energy consuming ionic pumps to maintain cellular integrity. In the present invention, these considerations are subsumed to the overriding goal to increase protein production.

Secondly, these salts include many ions which are utilized as enzymatic cofactors and intracellular messengers. Often, for some ions to be effectively transported into the cell, additional carrier molecules are needed in the medium. For example, in mammalian cell culture systems, transferrin is a carrier of iron.

As mentioned previously, although most mammalian cell culture media utilize glucose as the main carbon source, and although the present media likewise contain at least one carbohydrate, such as glucose, typically comprising a total of from approximately 5.5 to approximately 20 grams per liter in the medium, it has been found that, under certain circumstances, the media of the present invention may promote the utilization of alternative sources for carbon and energy. For example, the glucose of the present media does not serve as an energy source in the same manner as it does in conventional media (see Example 7 and FIG. 2C). These data indicate that the cells cultured in the present media shift from normal glycolysis to an alternative pathway. There is no indication that such a phenomenon would occur in any of the known prior art media. However, it is also noted that the cell cultures in the present system typically performed best when carbohydrate, such as glucose, was supplied in sufficient quantity so that it did not become depleted during the course of cell culture.

It is known that many animal cells grow best when attached to natural substrates like collagen, laminin, and fibronectin. It has been shown that the addition of ascorbic acid to cell culture medium increased the production and deposition of collagen by mammalian cells. See Engvall, E., et al. J. Cell Biol. (1986) 102:703-710. The production of collagen by cells in culture helps to create a natural matrix for growth. In a general basal media it is very difficult to define all the requirements that animal cells need for growth and protein production. Thus, the use of bovine or fetal bovine serum as a supplement in mammalian culture systems, has become a well accepted means of supplying various supplementary factors, the precise nature and requirements of which are not always capable of rigorous determination.

In the present invention, the utilization of media which is substantially saturated with various amino acid constituents, more typically at least one of the essential amino acids for a particular cell culture, has proven to be desirable in order to improve protein production, constrain cell growth and extend cell longevity. In addition, it is particularly preferred to supply at least all of the essential amino acids for a particular cell culture, and desirably all twenty recognized amino acids, as well as hydroxyproline and cystine, desirably all in each of the amino acid's individual substantially saturated concentration, in order to optimize protein production. It has been found to be desirable to include both cystine and cysteine in the present media, in spite of the fact that cysteine is more readily soluble and utilizable by cells in culture, as at the high concentrations utilized herein cysteine can display cytotoxic properties. Thus, the presence of cystine in the present media ensures an adequate supply of cysteine for cell growth and protein production, without the cytotoxic effects.

As stated above, the media of the invention will desirably contain approximately 5.50 to approximately 20 grams per liter of total or gross amino acids in solution, and the gross amino acids content of the present media desirable comprise at least 20%, and preferably from about 25% to about 50%, of the total dry weight of the medium constituents.

It will also be found useful to include an undissolved suspension of at least one of the amino acids in certain embodiments of the present media. In this manner the substantially saturated concentration of the amino acid is maintained in the aqueous solution of the media as the cell metabolism consumes the amino acid dissolved in solution.

Formulation and Production of Media

In view of the substantially saturated content of various substances of the present media, it is considered desirable to formulate the media in a manner that simplifies the dissolution of the various media constituents. One means of accomplishing this task is to formulate the various media constituents into components, or mixtures of dry powders, and bring such media components into solution either separately or in a step-wise fashion. In addition, heating the solution to temperatures above the range at which the solution will be utilized as cell culture media (typically a range of temperatures considered physiological) will also aid in the dissolution of the solid constituents, and in rendering the media substantially saturated at the designated temperature range. For example, the present media will typically be used at temperatures approximating 35-38° C. Thus, it may be desirable to saturate the medium with, e.g., the selected amino acid constituent by dissolving the constituent at a temperature in excess of the cell culture temperature so that the constituent will dissolve to a higher concentration, ordinarily while the aqueous solution is maintained in the range above 38° C., for example in the range of 40-50° C. In that manner, the aqueous solution may be substantially saturated, and depending upon the various physical conditions, the saturating constituents will be at approximately the point at which the constituents will precipitate out of solution (or will not continue to dissolve). When the temperature of the medium is then reduced for storage, e.g. typically to approximately 4° C., the solubility of the constituent in the medium is maintained, and the amino acid constituent does not then come out of solution.

In this manner also, the present media can be provided with an undissolved suspension of such constituents, such as at least one of the essential amino acids, in the aqueous solution. This permits maintenance of a substantially saturated concentration of the constituent in the aqueous solution as the cell metabolism consumes the constituent dissolved in solution. Ordinarily, the present media will be stored at ambient temperatures, such as room temperature or even refrigerated, below the temperatures employed for cell culture. Thus, the present media in storage will likely be super-saturated for one or more constituents, or an excess of undissolved constituent will likely be present under storage conditions.

Cell Cultures

Cells of any kind may be cultured in any of the methods of the invention. Cultures of antibody-producing cells, including hybridomas and other antibody producing cells, will derive particular benefit from the cell culture media of the present invention. The means to obtain such antibody-producing cell cultures are well known in the art. Hybridoma cell cultures, for example, are obtained by resort to the technology developed since the seminal work of Kohler and Milstein (1976).

Culture of recombinant protein-expressing mammalian cells, e.g., CHO cells, BHR cells, COS cells, Namalwa cells and the like, is an aspect of the invention. Many types of mammalian cells, which contain recombinant protein expression vectors, are well known in the art. See, e.g.:

-   Acklin, C, et al. “Recombinant human brain-derived neurotrophic     factor (THuBDNF). Disulfide structure and characterization of BDNF     expressed in CHO cells,” Int. J. Pept. Protein Res. (1993)     41:548-52; -   Fukushima, K., et al., “N-linked sugar chain structure of     recombinant human lymphotoxin produced by CHO cells; the functional     role of carbohydrate as to its lectin-like character and clearance     velocity,” ABB (1993) 304:144-53; -   Hayakawa, T., et al., “In vivo biological activities of recombinant     human erythropoietin analogs produced by CHO cells, BHK cells and     C127 cells,” Biologicals (1992) 7:139-50; -   Langley, K. E., et al., “Purification and characterization of     soluble forms of human and rat stem cell factor recombinantly     expressed by Escherichia coli and by Chinese hamster ovary cells,”     ABB (1992) 295:21-8; -   Lu, H. S., et al., “Post-translational processing of     membrane-associated recombinant human stem cell factor expressed in     Chinese hamster ovary cells,” ABB (1992) 298:150-8; -   Malik, N., et al., “Amplification and expression of heterologous     oncostatin M in Chinese hamster ovary cells,” DNA Cell Biol. (1992)     11:453-9; -   Nagao, M. et al., “Production and ligand-binding characteristics of     the soluble form of murine erythropoietin receptor,” Biochem.     Biophys. Res. Commun. (1992) 188:888-97; -   Rice, K. G., et al., “Quantitative mapping of the n-linked     sialyloligosaccharides of recombinant erythropoietin; combination of     direct high-performance anion-exchange chromatography and     2-aminopyridine derivatization,” Anal Biochem. (1992) 206:278-87; -   Schmelzer, C. H., et al., “Purification and partial characterization     of recombinant human differentiation-stimulating factor,” Protein     Expr. Purif. (1990) 1:54-62; -   Schmelzer, C. H., et al., “Biochemical characterization of human     nerve growth factor,” J. Neurochem. (1992) 59:1675-83; -   Sima, N., et al., “Tumor cytotoxic factor/hepatocyte growth factor     from human fibroblasts; cloning of its cDNA, purification and     characterization of recombinant protein,” Biochem. Biophys. Res.     Commun. (1992) 180:1151-8; -   Sun, X. J., et al., “Expression and function of IRS-1 in insulin     signal transmission,” J. Biol. Chem. (1992) 267:22662-72; -   Suzuki, A., et al., “Biochemical properties of amphibian bone     morphogenetic protein-4 expressed in CHO cells,” BJ (1993)     291:413-7; -   Tressel, T. J., et al., “Purification and characterization of human     recombinant insulin-like growth factor binding protein 3 expressed     in Chinese hamster ovary cells,” Biochem. Biophys. Res.     Commun. (1991) 178:625-33; -   Lucas, B. K., et al., “High-level production of recombinant proteins     in CHO cells using dicistronic DHFR intron expression vector,”     Nucleic Acids Res. (1996) 24:1774-9.

As the present media includes features which differ from those ordinarily found in the physiological environment from which the cultured cells were derived, it has been found to be beneficial to cell growth and longevity, and particularly to protein production, to adapt the cell cultures to the present media. This adaptation is typically accomplished by a period of passaging, or re-establishing the culture anew in fresh media, in accordance with well-known principles. Typically, such adaptation will be accomplished by daily passaging, e.g. at approximately 2×10⁵ cells/mL, and will be continued for a period of time until the viability of the inoculum culture is in excess of 90% before the protein-producing culture is established. Such adaptation can also be accomplished by passaging the cells through a series of media of ever-increasing osmolarity, such as 250 mOsm, 300 mOsm, 350 mOsm, 400 mOsm, and the like, naturally leading up to adaptation of the cultured cells to the osmolarity of the particular medium to be employed for protein production culture.

The invention having now been generally described, the same will be better understood by reference to the following detailed examples, which are provided for illustration and are not to be considered as limiting the invention unless so specified.

EXPERIMENTAL

In the experimental disclosure which follows, all weights are given in grams (g), milligrams (mg), micrograms (μg), nanograms (ng), or picograms (pg), all amounts are given in moles (mol), millimoles (mmol), micromoles (μmol), nanomoles (nmol), picomoles (pmol), or femtomoles (fmol), all concentrations are given as percent by volume (%), proportion by volume (v:v), molar (M), millimolar (mM), micromolar (μM), nanomolar (nM), picomolar (pM), femtomolar (fM), or normal (N), all volumes are given in liters (L), milliliters (mL), or microliters (4), and linear measurements are given in millimeters (mm), or nanometers (nm) unless otherwise indicated.

Example 1 Preparation of Medium BTC-28101

A dry powder form of Medium BTC-28101 was prepared as two separate components (A) and (B) as listed in Table I. The ingredients were milled to fine dry powder prior to use. To prepare the medium, Component (A) was dissolved in 90% by volume of pyrogen-free water. The mixture was warmed to around 40° C. and stirred for one hour to fully dissolve the powder and then cooled to room temperature. Component (B) was added and stirred another hour to dissolve. The pH was adjusted to 7.0 by addition of NaOH. Water was added to make up the desired volume. The osmolarity of the medium was in the range of 330-335 mOsm.

TABLE I Composition of Medium BTC-28101 in mg/L Component (A) Amino Acids Alanine 13.4 Asparagine•H₂O 189.2 Cystine•2HC1 105.4 Glutamic acid 79.4 Glycine 85.6 Hydroxyproline 63.0 Leucine 330.6 Methionine 98.4 Proline 110.6 Threonine 221.6 Tyrosine 174.0 Arginine HC1 1,162.9 Aspartic acid 80.0 Cysteine HC1•H₂O 105.4 Glutamine 1,997.2 Histidine HCl•H₂O 150.9 Isoleucine 314.8 Lysine HC1 394.6 Phenylalanine 148.6 Serine 170.2 Tryptophan 36.8 Valine 218.0 Component (B) Mineral Salts CaCl₂ (anh) 82.1 CuS0₄•5H20 0.00075 FeS0₄•7H20 0.220 KCl 372.8 MgSO₄ (anh) 52.4 NaCl 6,136.2 Na₂HPO₄ (anh) 484.1 ZnSO₄•7H20 0.23 Vitamins Bio tin 0.102 D-Ca pantothenate 1.240 Folic acid 8.800 Putrescine•2HC1 0.040 Niacinamide 1.510 Para-aminobenzoic acid 0.510 Pyridoxine HC1 0.520 Pyridoxal HC1 1.000 Riboflavin 0.210 Thiamine HC1 1.585 Vitamin B₁₂ 0.342 Carbohydrates and derivatives D-Glucose 6,846.0 Na Pyruvate 110.0 Nucleic acid derivatives Thymidine 5.7 Hypoxanthine 1.0 Lipids and derivatives Choline bitartrate 55.7 i-Inositol 104.5 Linoleic acid 0.020 Lipoic acid 0.050 Thiol compound Glutathione (reduced) 0.490 Buffers HEPES 3,570.0 NaHCO₃ 1,130.0 pH indicator Phenol red 6.0 The composition of the medium BTC-28101 was: Glucose (g/L) 6.846 Amino acids (g/L) 6.251 Amino acids (% d.w.*) 24.8 *dry weight of media ingredients

Example 2 Effect of Medium BTC-281010N Cell Growth, Viability and IgG Production

This example compares cell growth and monoclonal antibody production in two hybridoma cell lines 2HG11 (anti-human chorionic gonadotropin) and TBC3 (anti-human IgG) in the serum supplemented BTC-28101 medium of Example 1 versus DMEM/F12.

The cultures were established in shaker flasks with 100 mL media supplemented with 10% Fetal Bovine Serum (FBS). Inoculum cells were adapted and maintained by daily passaging at 2×10⁵ cells/mL with the respective fresh medium for at least a week, and the viability of each inoculum culture was above 90% before use. Batch culture was started by inoculating the cells at 2×10⁵ cells/mL into the respective medium. Samples were taken daily to follow the cell growth, by trypan blue staining and hemocytometer counting. Monoclonal antibody concentration in the culture supernatant was determined by ELISA analysis. The effect of the present media on cell growth is shown in FIG. 1. The maximum concentrations of Ig produced at the end of the cultures are summarized in Table II:

TABLE II Maximum Ig Concentration in Cell Cultures with BTC-28101 and Control DMEM/F12 Media Max Ig Concentration (μg/mL) Cell Line DMEM/F12 BTC-28101 2HG11 50 270 TBC3 84 450

Example 3 Effect of Medium BTC-281010N Cell Growth, Viability and Ig Production

Hybridoma cell line TH12 (anti-theophylline) was cultured in either the BTC-28101 media of Example 1 or a DMEM formulation. Cells were inoculated into 100 mL of BTC-28101 or control medium DMEM at 2×10⁵ cells/mL in 250 mL spinner flasks, both media were supplemented with 10% FBS. Similar procedures as stated in Example 2 were followed for preparing the inoculum cultures, and for monitoring the batch. TH12 produced higher concentrations of antibody in BTC-28101 than in the formulation of DMEM. As Table III shows, cell numbers and cell viability were also higher in BTC-28101.

TABLE III TH12 Batch Culture: Cell Counts and Viabilities TIME MEDIUM CELL COUNT VIABILITY D₀ BTC-28101   2 × 10⁵/mL 100% DMEM   2 × 10⁵/mL 90% D₁ BTC-28101 5.6 × 10⁵/mL 100% DMEM 2.6 × 10⁵/mL 100% D₂ BTC-28101 2.4 × 10⁶/mL 98% DMEM 0.8 × 10⁶/mL 91% D₃ BTC-28101   3 × 10⁶/mL 98% DMEM 2.2 × 10⁶/mL 97% D₄ BTC-28101 3.4 × 10⁶/mL 93% DMEM 1.4 × 10⁶/mL 77% D₅ BTC-28101 3.8 × 10⁶/mL 69% DMEM 0.5 × 10⁶/mL 32% D₆ BTC-28101 8.4 × 10⁵/mL 25% DMEM 3.6 × 10⁵/mL 20% D₇ BTC-28101 <5% DMEM <5% Viabilities in both Media were <5%. Total media volumes collected for analyses.

Table IV demonstrates enhanced Ig production and specific antibody titer when BTC-28101 is used.

TABLE IV TH12 Batch Culture: Ig Concentrations and Specific Antibody Titers TIME MEDIUM Ig mg/ML¹ TITER² D₁ BTC-28101 539 μg/mL 1,600 DMEM 447 μg/mL 400 D₂ BTC-28101 468 μg/mL 12,800 DMEM 397 μg/mL 3,200 D₃ BTC-28101 681 μg/mL 12,800 DMEM 440 μg/mL 6,400 D₄ BTC-28101 752 μg/mL 6,400 DMEM 518 μg/mL 3,200 D₅ BTC-28101 823 μg/mL 25,600 DMEM 553 μg/mL 6,400 D₆ BTC-28101 1,500 μg/mL   25,600 DMEM 489 μg/mL 6,400 D₇ BTC-28101 1,190 μg/mL   25,600 DMEM 560 μg/mL 3,200 ¹Ig concentrations determined by precipitating each sample with saturated ammonium sulfate and reading optical densities at 280 nm; mg/mL = O.D. 280 × dilution factor divided by 1.41 extinction coefficient. ²Specific antibody titers determined in an indirect ELISA with theophylline-BSA on the solid phase.

Example 4 Effect of Medium BTC-281010N Cell Growth, Viability and IgG Production

Hybridoma cell line DI16 (anti-Dirofilaria immitis) was cultured in either BTC-28101 or DMEM. Cell line DI16 produced higher concentrations of antibody in BTC-28101 than in the in-house formulation of DMEM. Table V shows that DI16 cell numbers and cell viability were also higher in BTC-28101.

TABLE V DI16 Batch Culture: Cell Counts and Viabilities TIME MEDIUM CELL COUNT VIABILITY D₀ BTC-28101   2 × 10⁵/mL 98% DMEM   2 × 10⁵/mL 98% D₃ BTC-28101 7.2 × 10⁵/mL 83% DMEM 8.4 × 10⁵/mL 99% D₄ BTC-28101 5.4 × 10⁶/mL 57% DMEM 1.5 × 10⁶/mL 26% D₅ BTC-28101 5.4 × 10⁶/mL 58% DMEM 1.5 × 10⁶/mL 8% D₆ BTC-28101 3.9 × 10⁵/mL 30% DMEM 0% D₇ BTC-28101 3.5 × 10⁵/mL 21% DMEM 0% D₈ BTC-28101 1.8 × 10⁵/mL 10% DMEM 0%

Table VI reports comparative Ig titers and concentration in the DI16 cell cultures.

TABLE VI DI16 Batch Culture: Ig Titers and Concentrations TIME MEDIUM Ig TITER¹ Ig mg/mL² D₃ BTC-28101 1:1,024 1.09 DMEM 1:256   0.770 D₄ BTC-28101 1:2,048 0.882 DMEM 1:512   0.926 D₅ BTC-28101 1:2,048 0.940 DMEM 1:512   0.654 D₆ BTC-28101 1:2,048 1.28 DMEM 1:512   0.746 D₇ BTC-28101 1:2,048 1.11 DMEM Culture Culture terminated terminated D₈ BTC-28101 1:2,048 1.39 DMEM Culture Culture terminated terminated ¹Ig titers determined by titrating samples in a mouse Ig capture ELISA. ²Ig concentrations determined by precipitating each sample with saturated ammonium sulfate and reading optical densities at 280 nm; mg/mb O.D. 280 × dilution factor divided by 1.41 extinction coefficient.

Example 5 Effect of Medium BTC-281010N Cell Growth, Viability and Ig Production

Hybridoma cell line NP11 (anti-N-acetylprocainamide) was cultured in either BTC-28101 or DMEM. This cell line was slightly slower than the other cell lines to respond to BTC-28101 with enhanced levels of antibody production (see Table VIIB); variations for different cell lines are not surprising. It is significant that the BTC-28101 culture produced substantial levels of antibody when cultures in DMEM were no longer viable (see Table VIIA). The ability to keep cultures producing for longer periods of time is a significant advantage of BTC-28101.

TABLE VIIA NP11 Batch Culture: Cell Counts and Viabilities TIME MEDIUM CELL COUNT VIABILITY D₀ BTC-28101   2 × 10⁵/mL 100% DMEM   2 × 10⁵/mL 100% D₁ BTC-28101 1.4 × 10⁵/mL 100% DMEM 2.3 × 10⁵/mL 100% D₃ BTC-28101   8 × 10⁵/mL 98% DMEM 1.04 × 10⁶/mL  84% D₄ BTC-28101 8.4 × 10⁵mL  72% DMEM 6.7 × 10⁵/mL 21% D₅ BTC-28101 1.2 × 10⁶/mL 72% DMEM 2.9 × 10⁵/mL 21% D₆ BTC-28101 8.4 × 10⁵/mL 52% DMEM   1 × 10⁵/mL 0% D₇ BTC-28101 7.6 × 10⁵/mL 41% DMEM 0% D₁₀ BTC-28101 1.3 × 10⁵/mL 5% DMEM 0%

TABLE VIIB NP11 Batch Culture: Ig Titers and Concentrations TIME MEDIUM Ig TITER¹ Ig mg/mL² D₀ BTC-28101 1:64  0.616 DMEM 1:64  0.542 D₁ BTC-28101 1:16  0.590 DMEM 1:16  0.488 D₃ BTC-28101 1:256 0.682 DMEM 1:256 0.659 D₄ BTC-28101 1:512 0.629 DMEM 1:256 0.730 D₅ BTC-28101 1:512 0.930 DMEM 1.256 0.777 D₆ BTC-28101 1:512 0.793 DMEM 1:256 0.887 D₇ BTC-28101   1:1,024 1.300 DMEM — — D₁₀ BTC-28101   1:1,024 1.240 DMEM — — ¹Ig titers determined by titrating samples in an indirect ELISA with N-acetylprocainamide-BSA on the solid phase. ²Ig concentrations determined by precipitating each sample with saturated ammonium sulfate and reading optical densities at 280 nm; mg/ml = O.D. 280 × dilution factor divided by 1.41 extinction coefficient.

Example 6 Effect of BTC-281010N IgG Production in Hollow Fiber Culture

Performance of the hybridoma cell line TH12 in a “mini” hollow fiber bioreactor (UniSyn Technologies, Inc.'s “Mini Mouse” bioreactor) cultured in FBS supplemented BTC-28101 was compared with the control FBS supplemented DMEM. The results are shown in Table VIII. Comparable levels of antibody were produced by this hybridoma in the control DMEM and in BTC-28101. However, the control culture was terminated after day 13 when viability was <10%. In distinction, the cells maintained in BTC-28101 remained highly viable, and the culture was terminated only because of shortage of medium supply.

TABLE VIII Comparison of Ig Titer of Hollow Fiber Culture in BTC-28101 and Control DMEM Media TIME BTC-28101 DMEM D₂ 1:6,400  1:51,200  D₅ 1:102,400 1:204,800 D₇ 1:204,800 1:204,800 D₉ 1:204,800 1:102,400 D₁₂ 1:204,800 1:102,400 D₁₄ 1:204,800 — D₁₆ 1:102,400 — D₁₉ 1:51,200  —

Example 7 BTC-28101 Medium—Hollow Fiber Bioreactors

This hollow fiber bioreactor example utilized a particular cell line GBI (Goodwin Biotech, Florida) that normally produces a few hundred μg/mL of MAB in conventional culture methods. FIG. 2A indicates that this cell line performed substantially better in BTC-28101. Data for pH of the medium (FIG. 2B), glucose utilization (FIG. 2C), and cell viability (FIG. 2D) are presented. Cells growing in BTC-28101 in hollow fiber bioreactors do not appear to utilize glucose from the medium at the rate normally seen with conventional media. Monitoring glucose utilization is a standard means of monitoring the progress of cells in bioreactors; ordinarily the higher the level of glucose utilization, the better the cells are growing. When using the medium BTC-28101, this rule does not appear to apply.

Example 8 BTC-28101 Medium—Spinner Flask Culture

Anti-theophylline hybridoma cells were inoculated into 250 mL of Difco's preparation of BTC-28101 or DMEM at 2×10⁵ cells/mL in 500 mL spinner flasks. Both media were supplemented with 10% FBS, 2% L-glutamine, and 1% pen-strep. Five mL samples were collected from each flask on the days indicated. Cell viability was determined each day samples were collected, and antibody concentrations were determined for all samples by radial immunodiffusion (RID) after all had been collected. Until that time, the samples (with cell material removed by centrifugation) were stored at −20° C. Antibody concentrations, as determined by RID, and cell viabilities are described in Table IX:

TABLE IX Comparison of Ig Concentrations and Cell Viabilities in BTC-28101 and DMEM Antibody (μg/mL) Cell Viability TIME DMEM BTC-28101 DMEM BTC-28101 D₀  <125* <125 95% 95% D₁ <125 <125 94% 95% D₃ <125 <125 95% 95% D₄ <125 <125 58% S6% D₇ <125 176 0 27% D₈ 562 0 21% D₉ 473 0 23% D₁₄ 1,035 0 19% *The lowest concentration RID standard used was 125 μg/mL.

It is significant that the cell line utilized produced 1 mg/mL under conditions described. Specifically, the spinner flasks did not provide ideal culture conditions. Once the culture was established, the medium was never replaced or replenished. Consequently, metabolites and dead cells continued to accumulate.

Example 9 BTC-28101 Medium—Spinner Flask Culture

Anti-theophylline hybridoma cells were inoculated into 100 mL of Difco's preparation of BTC-28101 or DMEM at 2×10⁵ cells/mL in 250 mL spinner flasks. All other parameters were as described by Example 8. Antibody concentrations, as determined by RED, and cell viabilities are described in Table X:

TABLE X Comparison of Ig Concentrations and Cell Viabilities in BTC-28101 and DMEM Antibody (μg/mL) Cell Viability TIME DMEM BTC-28101 DMEM BTC-28101 D₁  <125* <125 95% 99% D₃ <125 156 87% 99% D₄ <125 209 49% 74% D₅ <125 436 16% 65% D₆ <125 417  9% 39% D₇ <125 417 0 14% D₉ 400 0 10% *The lowest concentration RID standard used was 125 μg/mL. Note that the culture volume in Example 9 was one-half that in Example 8.

Consequently, nutrients may have depleted more quickly and metabolites or other materials accumulated in inhibitory concentrations more rapidly.

Example 10 Effect of BTC-281010N IgG Production in Serum-Free Culture

This example compares cell growth and monoclonal antibody production in a hybridoma cell line (2HG11) in serum-free BTC-28101 and other commercially available serum-free media available from Gibco.

Hybridoma 2HG11 has been adapted to serum-free conditions in the respective media. All media were supplemented with insulin, transferrin, ethanolamine and selenite. Cells were inoculated into 100 mL of BTC-28101 or control media at 2×10⁵ cells/mL in 250 mL shaker flasks. The effects on growth and IgG production are shown in FIGS. 3A and 3B.

Example 11 Preparation and Use of BTC-28102 to Culture Hybridomas

The nutrient content of Medium BTC-28101 was further enhanced to formulate medium BTC-28102. To prepare this medium, Component (C) was prepared according to the composition in Table XI and milled to dry fine powder. The powder was sterilized by gamma-irradiation and added to 100 mL of BTC-28101, constituting Medium BTC-28102. The osmolarity of the medium was approximately 400 mOsm.

TABLE XI Composition of Supplement to Medium BTC-28101 To Make Up BTC-28102 Component (C) in mg Alanine 2.0 Arginine HC1 174.4 Asparagine•H₂O 28.4 Aspartic acid 12.0 Cystine 2HCl 31.6 Glutamic acid 11.9 Glutamine 299.6 Glycine 12.8 Histidine HCl•H₂0 22.6 Hydroxyproline 9.5 Isoleucine 47.2 Leucine 49.6 Lysine HCl 59.2 Methionine 14.8 Phenylalanine 22.3 Proline 16.6 Serine 25.5 Threonine 33.2 Tryptophan 5.5 Tyrosine 26.1 Valine 32.7 Glucose 3,423

Cystine is utilized in lieu of cysteine, which is toxic to cells at high concentration.

The composition of medium BTC-28102 is:

Glucose 10.269 g/L Amino Acids 15.628 g/L Amino Acids (% d.w.) 41.1

Inoculum cells were adapted to Medium BTC-28101 following the protocol stated in Example 2 and inoculated into Medium BYC-28102 at 2×10⁵ cells/mL when starting the 100 mL shaker batch, along with the control cells in 100 mL of DMEM/F 12 medium. The effects of the present medium on cell growth are shown in FIG. 4. The maximum concentrations of Ig in the culture are summarized in Table XII.

TABLE XII Maximum Ig Concentration in the Cultures with BTC-28102 and Control DMEM/F12 Media Max Ig Concentration (μg/mL) Cell Line DMEM/F12 BTC-28102 2HG11 50 490 TBC3 84 1200

Example 12 Preparation and Use of BTC-28103 to Culture Cho Cells

This example illustrates use of the invention to culture mammalian cells that express natural or recombinant protein. BTC-28103 was prepared as described in Example 1 for the preparation of BTC-28101 but the buffer contents of HEPES and NaHCO₃ were increased to 8330 mg/L and 2650 mg/L, respectively. As a result, the osmolarity of the medium BTC-28103 was approximately 360 mOsm. Chinese hamster ovary (CHO) cells were adapted to grow in suspension and cultured in 100 mL of BTC-28103 and the control Iscove's Modified Dulbecco's Medium (IMDM) in shaker flasks, both supplied with 10% FBS, thymidine and hypoxanthine. Growth of the cultures was followed daily by hemocytometer counting and the results were as presented in FIG. 5.

The media of the invention are useful to culture protein expressing cell lines in the various forms of available bioreactors. In particular, selected media of this invention may be used as the intracapillary medium in hollow fiber bioreactor culture of recombinant protein expressing CHO cells.

Example 13 Comparison of Media Constituents

Table XIII compares selected constituents of the compositions of commercially available media RPMI, D/F and eRDF and of the media of the invention BTC-28101 (Example 1) and BTC-28102 (Example 11).

TABLE XIII RPMI D/F eRDF BTC-28101 BTC-28102 Glucose 2.00 3.15 3.42 6.846 10.269 (g/L) Amino acids 1.04 1.11 3.1 6.251 15.628 (g/L) Amino acids 5.6 6.6 16 24.8 41.1 (% d.w.)

The correlation of the percent amino acid content in selected media with the MAB production is presented in FIG. 6.

Novel cell culture media which improve the protein production by cells of all types, including mammalian cells which express recombinant protein vectors, have been disclosed. The media of the invention will substantially enhance the cost effectiveness of cell culture procedures generally, including the production of monoclonal antibodies.

All patents and patent applications cited in this specification are hereby incorporated by reference as if they had been specifically and individually indicated to be incorporated by reference.

Although the foregoing invention has been described in some detail by way of illustration and Example for purposes of clarity and understanding, it will be apparent to those of ordinary skill in the art in light of the disclosure that certain changes and modifications may be made thereto without departing from the spirit or scope of the appended claims. 

1-32. (canceled)
 33. A method for culturing animal cells, comprising: (a) providing an animal cell; (b) providing a cell culture medium comprising: 1) a total of from approximately 5.5 to 20 grams per liter of a plurality of amino acids; and 2) at least one carbohydrate; and (c) growing the animal cell of (a) in the medium of (b), wherein the utilization rate of the carbohydrate source as an energy source by the animal cell is altered as compared to the utilization rate in a conventional medium, thereby culturing cells.
 34. The method of claim 33, wherein the animal cell utilizes an alternative source of carbon.
 35. The method of claim 33, wherein the utilization rate of the carbohydrate source as an energy source by the animal cell is lower as compared to the utilization rate in a conventional medium.
 36. The method of claim 33, wherein the animal cell does not utilize the carbohydrate source as an energy source.
 37. The method of claim 33, wherein the cell produces at least one protein of interest and production of the at least one protein of interest is increased relative to the production of the at least one protein of interest produced by the same cell grown in the conventional medium.
 38. The method of claim 35, wherein the conventional medium is selected from the group consisting of: DMEM, DMEM/F12, eRDF, and RPMI.
 39. The method of claim 33, wherein the cell produces at least one protein of interest and production of the at least one protein of interest is increased at least about two-fold relative to the production of the at least one protein of interest produced by the same cell grown in the conventional medium.
 40. The method of claim 33, wherein the cell produces at least one protein of interest and production of the at least one protein of interest is increased at least about five-fold relative to the production of the at least one protein of interest produced by the same cell grown in the conventional medium.
 41. The method of claim 33, wherein the cell produces at least one protein of interest and production of the at least one protein of interest is increased at least about ten-fold relative to the production of the at least one protein of interest produced by the same cell grown in the conventional medium.
 42. The method of claim 33, wherein the cell remains viable for a longer period of time in continuous culture without the replenishment or exchange of growth medium as compared to the time the same type of cell remains viable when grown in the conventional medium.
 43. The method of claim 42, wherein the conventional medium is selected from the group consisting of DMEM, DMEM/F12, eRDF, and RPMI.
 44. The method of claim 33, wherein the cell remains viable for at least twice as long as the same type of cell grown in the conventional medium.
 45. The method of claim 33, wherein the cell remains viable for at least five times as long as the same type of cell grown in the conventional medium.
 46. The method of claim 33, wherein the cell is a hybridoma cell or a myeloma cell and the at least one protein of interest is an antibody.
 47. The method of claim 33, wherein the cell comprises a recombinant protein expression vector and the at least one protein of interest is a recombinant protein expressed by the vector in the cell.
 48. The method of claim 47, wherein the cell is a mammalian cell.
 49. The method of claim 48, wherein the mammalian cell is selected from the group consisting of a CHO cell, a BHK cell, a COS cell, and a Namalwa cell. 